Researchers at the National Graphene Institute, based in Manchester, have published a study in Nature unveiling a groundbreaking discovery in the realm of energy harnessing and information computing. The research led by Dr Marcelo Lozada-Hidalgo focuses on how electric field effects can selectively accelerate electrochemical processes in graphene, a material crucial for renewable energy technologies. By decoupling proton-related processes in graphene electrodes, the team has achieved unprecedented control over electrochemical reactions, challenging previous assumptions and offering new possibilities for energy applications. The study specifically examines proton transmission and proton adsorption processes in graphene, essential for hydrogen catalysts and electronic devices, respectively. The researchers found that electric field effects can independently drive these processes, presenting a new method to control electrochemical reactions. The implications of this discovery extend to energy technologies like hydrogen catalysts and fuel cells, with potential applications in complex processes such as CO2 reduction. Furthermore, the study hints at new computing networks utilizing graphene devices for dual functionality as memory and logic gates. The National Graphene Institute, known for its expertise and cutting-edge facilities, continues to advance research in 2D materials, setting the stage for transformative industrial applications in various key areas.